SE524663C2 - Gas cell, included in gas sensor for spectral analysis - Google Patents

Abstract

The present invention relates to a gas cell which is included in a gas sensor and adapted to establish the presence of a gas and/or for determining the concentration of one such gas (G), comprising a cavity (2') which is delimited by wall portions that have light reflecting properties and which is intended to enclose a volume ((G)) of said gas, and further comprising a light source (3) which is adapted to emit a light bundle (3a') directed for reflection between cavity-associated and opposing wall portions, wherein a light bundle (3a'') is comprised of light rays which are reflected in a concave wall mirror surface (2b') and adapted to be directed onto one or more light receivers (4, 5) which function to detect an absorption wavelength corresponding to the gas sample ((G)). The concave curved wall mirror surface (2b') is adapted to reflect an obliquely received divergent light bundle (3a') from the light source (3) onto a flat grating-allocated cavity-associated wall surface (2g') whose reflecting surface includes or is structured as a Littrow arrangement (2g''). The light bundle (3a'') is adapted to fall onto the flat wall surface (2g') at an angle which lies close to the Blaze angle of the grating wherewith, inter alia, an absorption wavelength corresponding to the chosen gas sample ((G)) and present in the light bundle (3a'') is caused to be reflected and diffracted ((3a'')) by said flat wall surface (2g'') in a straight opposite direction so as to be reflected again in said curved mirror surface (2b') and directed diffracted towards each of said light receivers (4, 5).

Description

524 663 2 have the presence of one or fl of your selected gases and / or such a gas exhibiting a concentration evaluated. There is nothing to prevent one or more of said light receivers from being used as a reference signal.

A display unit is connected to said electronic circuits, to visually indicate gas presence and / or gas concentration.

Gas cells of the associated type comprise a, lighter fl ectating properties exhibiting wall portions delimited, cavity, intended to enclose a volume of said gas or gas mixture intended for the measurement itself.

Gas cells of this kind also have or cooperate with a light source, preferably one which produces a light emitting within the visible frequency range or, in certain applications, an IR beam emitting light source, adapted to emit a directed light beam, such as directed to be reflected between cavities. belonging and opposite wall portions.

The light beam must, by means of the required reflecting means, be built up of diverging light beams, which are directed towards and are reflected in a concavely curved wall portion, in order to be adapted by means of said wall portion to be able to converge towards one or your light receivers.

Such a light receiver is then adapted to have the light intensity of its selected light-absorbing wavelength or wavelengths sensed via electronic circuits within a light spectra corresponding to the gas, by utilizing a reduction of certain or certain gas-significant wavelengths significant for spectral analysis.

Light receivers of this kind are connected to electronic circuits in order to be able to sense in a known manner the intensity of the wavelengths of light spectrum that are subject to a valuation, and the intensity of a reference wavelength, related to the current light intensity related to the light source. BACKGROUND OF THE INVENTION Methods and arrangements, of the above kind, are previously known in a number of different embodiments.

As a first example of the prior art and the technical field to which the invention relates, mention may be made of a gas sensor utilizing infrared (1R) spectrometer technology, according to U.S. Patent Publication US-A-5,550,375.

Here is shown and described an arrangement which utilizes the principle that a gas and / or a gas exhibiting concentration can be selectively detected by having an IR spectrometer used, by determining the specific absorption wavelengths of the gas and evaluating the intensity of these gas-significant wavelengths within the infrared spectral range. .

The gas sensor indicated here is specially adapted to be able to continuously control a gaseous flow or a cavity filled with gas, where the sensor or cell body consists of a single part and is manufactured as a body with a microstructure.

The cavity in the gas cell is formed with a wall-related mirror grid, placed between the inlet and outlet openings for IR rays.

The embodiment according to Figure 1B shows that a light beam, with diverging beams, is emitted from the light source (7) through a gap or aperture (3) towards a first concave mirror surface (5), is then re-reflected obliquely towards a flat lattice surface (2) and from there is re-reflected. or is diffracted obliquely, like a light wave, towards an adjacent concave second mirror surface (8), in order to be able to pass through the exit opening (4) as a converging light beam.

Here it is shown that the body or a base plate (1) for the gas cell can be produced via X-ray, lithographic etching, electroplating and casting via the "LlGA" process. 524 663 As a second example of the prior art and the technical field to which the invention relates, mention may be made of a gas sensor, shown and described in the international patent publication WO-A1-98 / 09152.

Shown here is a gas sensor (A), adapted to be able to evaluate the contents of a gas sample, enclosed in a cavity (2) or gas cell.

The gas cell has here been given a shape of a block, where walls and wall sections for the cavity show a very high light-reflecting ability and are called mirror surfaces (11A, 12A).

The cavity (2) has been assigned an aperture (2a) for incoming light beams and which are to be reflected within the cavity a preselected number of times, thereby allowing them to en nier a required measuring distance, before the light beams pass an aperture (6) for outgoing light beams.

More specifically, the use of three opposite and concave light-reflecting wall portions (11, 12, 13) within the gas cell is shown.

A first wall portion (11) is assigned a shape adjoining a half ellipse or ellipsoid.

A second (12) and a third (13) of these wall portions have an equivalent shape adjoining a portion of a half ellipse or ellipsoid.

The design is based on the use of a “Littrow” arrangement, where a large angle of incidence towards a lattice surface will see the double diffraction angle.

DESCRIPTION OF THE PRESENT / PROVISION TECHNICAL PROBLEMS Considering the fact that the technical considerations that a person skilled in the relevant technical field must make in order to be able to offer a solution to one or more technical problems posed is initially a necessary the measures and / or the sequence of measures to be taken, and the necessary choice of the means or means required, the consequent technical problems should, as a result, be relevant in the creation of the present invention.

Taking into account the prior art, as described above, it should therefore be seen as a technical problem to be able to realize the significance of and the advantages associated with having a gas cell created, included in or connectable as a gas sensor, which can exhibit the initially given the conditions and which can be given a very compact shape, but can still offer a sufficiently long optical measuring range within the cavity of the gas cell to be able to perform an accurate spectral analysis, using one or fl your current absorption wavelengths, for a certain or certain selected gases via electronic circuit- Saf.

It should be seen as a technical problem to be able to create such conditions with simple measures and means that a desired evaluation of one or fl your gases and / or one or fl your gas concentrations can take place with high resolution and with high efficiency.

It will also be a technical problem to be able to realize the measures required to significantly increase the length of the measuring distance and for this purpose to have a reactor design used for the utilized light source in the first place.

In addition, there is a technical problem in being able to realize the significance of and the advantages associated with primarily having an optical measuring range appearing within the cavity intended for the gas sample and light fl sections and diffractions and secondly having an additional optical measuring range appearing within the reflector construction.

There is then a technical problem in being able to realize the importance of and the benefits associated with having such a geometric shape created for a gas cell, with a gas sample intended and light fl sections offering cavity, where the chosen shape allows one or fl your light receivers to be able to be placed, however side-by-side, in front of a radiant light source or side-related, slightly in front, next to or slightly behind, a reflected or virtual light source.

In addition, there is a technical problem in being able to realize the significance of and the advantages associated with having a selected number placed, such as at least two, light receivers next to and outside a reflector design and next to and outside one, via the reflector for the light source emitted, converging and / or or diverging beam of light.

There is then a technical problem in being able to realize the significance of and the advantages associated with allowing a cavity-forming concave curved wall portion to be adapted to allow an oblique and at a small angle incident and received divergent light beam to be reflected from the light source towards a plant, lattice-assigned and cavity-associated wall portion.

There is then a technical problem in being able to realize the significance of and the benefits associated with allowing the flat wall portion and its reflecting and diffracting surface to be displayed or to be structured as a, per se previously known, “Littrow” arrangement. .

In addition, there is a technical problem in being able to realize the significance of and the advantages associated with allowing the curved light-reflecting surface to be assigned a shape that adheres to the shape and curvature of a section of a parabola line and thereby realize that it is flat, brighter lattice-assigned, the wall portion shall form an angle, which creates conditions for allowing a diffracted wavefront to be reflected.

There is also a technical problem in being able to realize the significance of and the advantages associated with being able to create such conditions within the cavity that the light beam or wavefront must be adapted to fall against said flat wall portion at a selected angle, namely that close to a lattice assigned "B | aze" angle. 524 7663 There is a technical problem in being able to realize the significance of and the advantages associated with allowing one or more wavelengths within the light beam, corresponding to the selected gas or gases, to be caused to be refracted and diffracted by said flat wall portion in a straight line. "Opposite direction, in order to be re-reflected as a diffracted wavefront in said curved surface and thereby be allowed to re-reflect the selected wavelength or selected wavelengths in a direction towards, however somewhat adjacent to, said light source.

There is also a technical problem in being able to realize the significance of and the advantages associated with allowing said curved wall portion to connect to a part of the curved shape formed by a parabolic line or parabolic arc.

It would then be a technical problem to be able to realize the significance of and the advantages associated with allowing said part of the curved shape to be located close to the vertex of a parabola line and close to the focus of said parabola line.

In addition, there is a technical problem in being able to realize the significance of and the advantages associated with having said part of the curved shape limited to a point or section oriented perpendicular to an axis assigned to the parabola line and through a related focus or focal point.

There is also a technical problem in being able to realize the significance of and the advantages associated with allowing the image of a physical light source via a reactor design to be virtually placed or appear in or adjacent to a parabola form associated with focus or focal point.

It should also be seen as a technical problem to be able to realize the significance of and the advantages associated with allowing said curved wall portion of said cavity to be constituted by the part of a parabolic arc which is oriented only on one side of a parabolic shape axis.

There is a technical problem in being able to realize the significance of and the advantages associated with allowing the flat grid-assigned cavity-associated wall portion to be assigned 524 8663 a grid structure with a “Blaze” angle, to offer a reaction and a diffraction in one, however, approximately, in the exact opposite direction.

There is also a technical problem in being able to realize the significance of and the advantages associated with allowing the lattice structure and other measures to be adapted to be able to offer only a first-order diffraction grating.

In addition, there is a technical problem in being able to realize the significance of and the benefits associated with allowing the "Blaze" angle to be chosen between 50 ° and 60 °.

Furthermore, it should be seen as a technical problem to be able to realize the significance of and the benefits associated with allowing one or fl your, for diffracted wavelengths, light receivers to be located close to the physical light source and / or near the virtual light source and with their reception lobes directed towards the associated surface sections, within the parabolic-shaped curved surface.

In addition, there is a technical problem in being able to realize the significance of and the advantages associated with being able to create such conditions that a plurality of light receivers can be placed next to a focus or a focal point for said parabola shape.

There is also a technical problem in being able to realize the significance of and the advantages associated with allowing said cavity to be formed by two polymer-based replicas, which have been treated to give selected wall portions lighter fl ectated properties.

There is also a technical problem in being able to realize the significance of and the benefits associated with allowing an utilized light source to consist of an incoherent light source, for generating a wavelength spectra within the IR range.

There is also a technical problem in being able to realize the significance of and the advantages associated with allowing a physical light source or a virtual light source to be placed in or close to a focus or a focal point, assigned to the parallel concave curved surface. .

There is a technical problem in being able to realize the significance of and the benefits associated with allowing one or more of your light receivers to be placed close to or in a focal point, assigned to the parabolic concave curved surface.

There is a technical problem in being able to realize the significance of and the advantages associated with allowing a physical light source to be placed in one focus or focal point of an elliptical shape or ellipsoid shape and that in the other focus or the other focal point is placed an optically adapted detector system. fi lter, in or near a virtual light source appearing there.

There is a technical problem in being able to realize the significance of and the advantages associated with allowing the optical filter to be adapted to allow the passage of light-related wavelengths within a free spectral range applicable to the detector system.

There is also a technical problem in being able to realize the significance of and the advantages associated with allowing said optical filter to be adapted to filter out or block wavelengths shorter than the wavelengths coordinated within the selected, for the detector system, free the spectral range.

SOLUTION The present invention is based on the initially known prior art, in which a gas sensor is adapted to determine the presence of one or more gases and / or is adapted to determine a concentration exhibiting the gases.

The gas sensor requires a gas cell, comprising a, light-reflecting property exhibiting wall portions defined, cavity, intended to enclose a first volume of said gas intended for a measurement, a light source, adapted to emit a light beam directed to be reflected between cavity members 66 and opposing members. 10 wall portions, where this light beam is formed by b | .a. divergent light rays, which, reflected in a concave wall portion, are adapted to be directed at one or more of their light receivers and which are adapted to detect occurring light intensity via electronic circuits in one or two corresponding corresponding wavelengths of gas.

In order to be able to solve one or more of the above-mentioned technical problems, the present invention specifically indicates that the prior art should be supplemented by said concavely curved wall portion being adapted to have an obliquely received light beam reflected from the light source against a flat grid-assigned cavity-associated wall portion.

The flat wall portion shall then have a reflecting surface, having one or being structured as a "Littrow" arrangement, and where the light beam is adapted to fall towards said flat wall portion at an angle which is close to the "B | aze" of the grating. Angle.

This creates conditions for allowing one or fl era, corresponding to the selected gas, absorption wavelengths within the light beam to be allowed to be reflected and diffracted by said flat wall portion in a “straight” opposite direction, to be refracted again refracted in said curved wall portion or fl your reflected wavelengths, and may be directed at said light receiver.

As proposed embodiments, falling within the scope of the basic idea of the present invention, it is indicated that said curved wall portion should adhere to the curved shape which is valid for a parabola shape.

A physical light source must then, via a reactor or reactor construction, be able to virtually appear and be placed in or near a focus or focal point belonging to a parabola form.

Said curved wall portion shall then consist of a part of a parabolic arc, oriented on one side of an axis of a parabolic shape. 524 663 More specifically, it is pointed out that the flat grid-assigned cavity-associated wall portion should be assigned a grating structure with a "Blaze" angle for reflection and / or diffraction in the exact opposite direction and where the grating structure and other measures should be adapted for a first, and possibly a second, the diffraction grating of the order.

It is further stated that the "Blaze" angle should be selected between 50 ° and 60 °.

The invention also offers that one or fl your light receivers should be able to be located close to the light source and / or a virtual light source and where the receiving lobes of utilized light receivers should be directed towards the curved surface.

More specifically, it is indicated that said cavity shall be formed of two polymer-based replicas, which have been treated to impart light-reflecting properties to selected wall portions.

The invention also provides that the light source is to be an incoherent light source for generating a wavelength spectra within the IR range.

The invention further provides that a physical light source or a virtual light source should be located close to or in a focal point, assigned to the concavely curved surface, while one or more light receivers should be able to be located in or close to said focal point.

The invention further indicates that a physical light source should be located in one focal point or focus of an elliptical shape or an ellipsoid shape and that in or next to the other focal point or focus, and the virtual light source appearing there, an optical filter is placed.

Said optical filter shall be adapted to allow the passage of light-related wavelengths within a free spectral range applicable to the detector system, and more particularly it is said that said optical filter shall be adapted to filter away and block wavelengths shorter than wavelengths coordinated within the free spectral range. 52412663 ADVANTAGES The advantages which can mainly be considered to be characteristic of the present invention and the special significant features indicated thereby are that in this way conditions have been created to be able to offer in a simple manner a production of a gas-adapted gas cell, where a cavity, a light source and one or fl your light receivers are coordinated into a compact unit and directly adapted to each other to evaluate one or fl your selected gases and / or gas mixtures.

A parabola-shaped curved light-vägg-rectangular wall portion within the cavity should re-ett an incoming divergent light beam as a wavefront against a flat lattice-assigned wall portion, which in turn diffractively re-reflects a wavefront with selected wavelengths back to the curved surface, which in turn diffuses against one or fl your light receivers, in order to be able to determine with the aid of an evaluated light intensity within selected or selected absorption wavelengths the presence of one or fl your gases and / or the gas concentration.

What can primarily be considered to be characteristic of the present invention is stated in the characterizing part of the following claim 1.

BRIEF DESCRIPTION OF THE DRAWINGS An presently proposed embodiment, exhibiting the significant features associated with the present invention, will now be further described, by way of example, with reference to the accompanying drawings, in which; Figure 1 Figure 2 Figure 3 Figure 4 Figure 5 Figure 6 Figure 7 524 663 13 shows in principle and in block diagram form a gas sensor, comprising a, structured according to the instructions of the invention and flowable by a gas. gas cell, with a light source and two light receivers, connected to electronic circuits with a display unit, shows in plan view an enlarged view of the gas cell with its cavity structure, a light source and two light receivers, but without electronic circuits to operate the light source and receive and evaluate the light intensity for the relevant absorption wavelength or wavelengths related to a selected gas, shows the choice of system design and "Blaze" angle, when these are selected in view of a appearing lattice structure crystalline silicon, shows more precisely an utilized embodiment of a "Littrow" - arrangement, assigned to a flat, lighter fl rectifying and wavelength diffractive wall portion, shows in plan view the gas cell according to fi figure 2, where brighter fl section and wavelength or light diffraction are plotted for a gas cell, adapted to evaluate the presence of the gas C02, current concentration shows in a graph the variation of the efficiency with respect to the wavelength for a "Littrow" arrangement and shows in a graph the detectors' wavelength-related reception in relation to the percentage of the light source's emission. 524 663 DESCRIPTION OF THE EMBODIMENT OF THE CURRENT EMBODIMENT It should then be pointed out at the outset that in the following description of a presently proposed embodiment, which exhibits the significant features associated with the invention and which is clarified by the drawings shown hereinafter. and a special terminology for the purpose of clarifying the idea of invention in the first instance.

In this context, however, it should be borne in mind that the terms chosen here should not be construed as limiting only the terms used and chosen here, but it should be understood that each term thus chosen should be interpreted so as to include all technical equivalents operating on the same or essential terms. in the same way in order to be able to achieve the same or substantially the same intention and / or technical effect.

With reference to Figure 1, the basic preconditions for the present invention and where the significant peculiarities associated with the invention are generally concretized are shown there in a schematic and principled manner, through an embodiment now proposed and described in more detail below.

The basic construction of a gas sensor 1, according to Figure 1, is per se previously known.

The invention primarily comprises the utilized gas cell 2, with a unique orientation of a physical light source 3 and a unique coordination of a number of light receivers, where the embodiment shows two side-related light receivers 4 and 5.

A person skilled in the art realizes that the number of light receivers 4, 5 can vary as well as the physical location of the light receivers, all depending on the selected gas or gases or a selected gas mixture and the shape of the cavity within the gas cell 2.

For the sake of simplicity only, therefore, the following description of a proposed embodiment has been illustrated with two side-related light receivers, where one light receiver 4 is located and adapted for an absorption wavelength corresponding to the selected gas while the other light receiver 5 is located and adapted for to serve as a reference wavelength.

With the aid of this, the signal in the receiver 4 can be normalized to become substantially independent of the possibly varying light intensity of the light source 3, which in any case occurs with aging.

For this purpose, the gas cell 2 comprises, according to Figure 1, a light-reflecting property having opposite wall portions delimited, cavity 2 ', schematically delimited by a first side-related wall portion 2a, a second side-related wall portion 2b, a third side-related wall portion 2c and a fourth side-related wall portion 2d.

Said side-related wall portions 2a, 2b, 2c and 2d are in cooperation with a flat bottom portion 2e and a flat roof portion 2f, oriented parallel to each other.

Thus, wall portions or wall surfaces 2a, 2b treated for light-reflecting properties have been assigned reference numerals 2a ', 2b' and so on. and may in the following description be referred to as mirror surfaces 2a ', 2b' and so on.

In principle, it is required that a light beam "L" from the light source 3 should pass the said cavity 2 'and here simplified is reflected by the mirror surface 2b' and directed towards and received by the light receiver 4 (or 5) in a manner known per se. The light beam “L” de fi- thus initiates a cavity-enclosed optical measuring distance through an enclosed gas sample (G).

Different gases and different gas mixtures require different lengths of optical measuring distances and this can be offered by enlarging the dimensions of the cavity or creating conditions for a number of reaction portions or points between the light source 3 and receiver 4, 5. 524 663 16 Thus fi gur 1 in block diagram form shows a for a gas “G” flowable gas cell 2 and which gas cell 2 will enclose a gas sample (G) intended for an electronic evaluation.

The gas cell 2 designated according to the invention, according to Figure 2, is adapted to be able as a unit to cooperate with electronic circuits 6, in order to be able to operate a gas cell-associated light source 3 and detect signals occurring on one or more of their light receivers 4, 5. , in order to be able to evaluate the instantaneous light intensity, related to a selected absorption wavelength or wavelengths or alternatively related to a selected reference wavelength or reference wavelengths, and accordingly have the presence of a selected gas "G" and / or such a gas exhibiting concentration.

A display unit 7 is connected to said electronic circuits 6 for visually indicating on a display surface or screen 7 'only a gas deposit or a gas deposit having a concentration.

With reference to Figure 2, there is shown in plan view in more detail a gas cell 2, in accordance with the present invention, and the geometry and structure of which will be described in more detail in the following.

The gas cell 2, according to Figure 2, has a rather complicated shape and primarily defines a cavity 2 'or space adapted for a gas sample (G), which will be described in more detail below.

The actual optical measuring distance is in a first embodiment developed within said space, designated a second space "K2".

All the inner wall portions of the cavity 2 '(except for the wall portions 3d, 3e), with associated bottom portion and roof portion, are surface-treated in a manner known per se, in order to exhibit high light-reflecting properties therefrom. The gas cell 2 with its cavity 2 'is to be considered thin, in that the wall portions 2a, 2b, 2c and 2d are chosen very narrow and the bottom portion 2e and the roof portion 2f are placed close to each other.

The height dimension is selected for 2 gur 2 to correspond to the required height for the light source 3, which can be calculated to 3 to 5 mm.

The cavity 2 'can here be considered to consist of two different spaces, a first space "K1", with a physical light source 3 and a reactor or reactor construction, and a second space "" K2 ", with the function of primarily letting one for the gas sample (G) measuring chamber, the cavity 2 'and its second space "K2" have here a first opening 21 for an access of a gas intended for the measurement "G" and a second opening 22 for exit or outlet of the intended and used for the measurement the gas The first space “K1” is shaped to enclose a radiating physical light source 3, adapted to emit a directed and converging light beam 3a, towards and through an aperture 3b using a reflector or reactor structure 3c_ This first space ” K1 'has, as said reactor 3c, a partially elliptical or ellipsidally shaped sub-portion (K1') and a connecting sub-portion (K1 "), which has a tapered shape.

The omnidirectional physical light source 3 is located in one focus or the focal point “F1” of the elliptical cavity (K1 '), whereby divided omnidirectional light rays from the light source 3 will be re-echoed by the rejector 3c towards a second focus or focal point “F2” , and there forms a virtual image of the physical light source, assigned the reference numeral (3 ').

The second or connecting sub-section (K1 ”) is shown here delimited by two converging wall sections 3d and 3e. 524 663 The light rays from | juskä || an 3 are reflected partly in an elliptical curved mirror surface belonging to the rector 3c towards focus “FZ” and partly a direct radiation takes place from | jus- source 3 towards focus “F2”.

The wall portions 3d and 3e are adapted with a mutually converging shape in order to thereby en form an aperture angle "a", for the first space "K1" and must then be shaped or treated to avoid light reactions or as an alternative exhibit deficient reflective properties.

The wall sections 3d, 3e can in the latter case then be "landed" or "black".

A light beam 3a ', with a divergence angle "a", can now be considered or considered to start from a point-shaped virtual light source (3') from the focal point or focus "F2" and thereby form, within the second space "K2", divergent light beams, which , obliquely reflected in a concave wall portion 2b, with a treated wall surface or mirror surface 2b '. This diverging light beam 3a 'is completely reflected in said concave mirror surface 2b' and is thereby adapted to be directed as a wavefront towards an opposite second, a flat, wall portion 2g, with a treated wall surface 2g, for a diffraction of received light beams and wavelengths. ', of a construction which will be described in more detail below.

A diffracted light with a selected wavelength or wavelengths having a wavefront is reflected from the flat wall surface 2g 'towards the concave wall surface or mirror surface 2b' to be directed therefrom back towards the virtual | juskä || an (3 '), but with relevant absorption wavelength alternatively absorption wavelengths directed to hit one or more light receivers, such as the light receivers 4 resp. 5, in a manner to be described in more detail below and with reference to Figures 5, 6 and 7.

The light receiver 4 and each other utilized light receiver (such as the light receiver 5 and other light receivers not shown) are adapted to allow the light intensity to be received and sensed in the corresponding and diffracted absorption wavelength, while other light receivers similarly have their instantaneous light intensity sensed. absorption wavelength. 524 663 The flat grid-assigned cavity-associated wall surface 2g 'thus has a brighter fl-rectifying, light-diffracting or wavelength-diffracting, surface and where this surface 2g "is structured as a known" Littrow "arrangement.

The light wave 3a 'totally ignored by the wall surface 2b', with parallel light beams, is adapted to fall towards said wall portion 29 and wall surface 2g 'at an angle of incidence which is close to the "Blaze" angle of the grating.

In "Springer Series in Chemical Physics" volume 5 "Laser Spectroscopy" the conditions for a "Littrow" arrangement and a "Blaze" angle are shown on pages 132 and 134.

In the case of the space "K2" and the gas sample (G) enclosed in said space "K2", the optical length of the light beam 3a ', the optical length of the reflected wavefront 3a ", the diffracted wavefront (3a"), the reflected refracted and diffracted light rays from the concave surface 2b ', inter alia towards the receiver 4, to constitute the total and effective optical measuring distance through the trapped gas sample (G).

According to a proposed second embodiment of the inventive gas cell 2, the length of the measuring distance can be increased by also including an optical measuring distance within the first space "K1" by allowing the gas "G" to also pass in through an opening 21 'and out through an opening 22 ”.

Each selected wavelength within the light beam 3a "and the wavefront 3a" is now caused to be reflected and diffracted by said flat wall surface 2g 'in a "straight" opposite direction as a diffracted light wave with different wavelengths, denoted (3a "), so as to reflect wavelength separately said curved surface 2b 'and thereby allowed to pass, as an absorption waveLength-related light beam 3f, towards said light receiver 4.

By the expression "straight" opposite direction, however, is meant an insignificant difference and a reaction angle which deviates only slightly from "zero". 524 663 20 It is important here that the selected absorption wavelength to be measured will not occur in or near the virtual light source (3 ').

The shape of the curved wall surface 2b ', in Figure 2, adheres to the curved shape that applies to a mathematical parabola function.

Light beams towards and from the reactor or reactor surface 3c converge, via a converging light beam 3a, towards the focusing or focal point "F2", exposing the virtual light source (3 ') and this should be able to be oriented in or rather close to a focal point or focal point "F3" for the parabolic curved wall surface 2b '.

Said curved wall surface 2b 'thus consists of a parabolic arcuate wall portion (2b'), oriented on one side of an axis of a parabolic shape 2b ''.

The lattice structure 29 ”on the wall surface 2g 'is, together with other measures, adapted as a first-order diffraction grating.

The "B | aze" angle is thus selected depending on the selected absorption wavelength and will in practice have angular values between 50 ° and 60 °.

The embodiment according to Figure 2 illustrates that two slightly separated light receivers 4, 5 are located outside the first space “K1” and close to the virtual light source (3 ') and directed with their receiving lobes 3f resp. 3h towards the curved surface 2b 'and the wall portion (2b'), in order thus to be able to receive different absorption wavelengths representative of the gas or gases.

More specifically, the invention indicates that said cavity 2 'may be formed of two polymer-based replicas, which have been treated in a separate process to impart good light-refracted properties to the wall portions and wall surfaces. The light source 3 is also constituted by an incoherent light source, for generating a wavelength spectra within the 1R range, and thus the light source 3 can be assigned the shape of a filament 30, enclosed by a quartz glass 31.

The rectifier 3c is formed in Fig. 2 along an elliptical shaped line 3c 'as a flat elliptical curved surface, extending a distance past one focus "F1", a distance corresponding to a selected distance between, said focus "F1" and a vertex, designated "V1 The curved elliptical line 3c 'connects distally to the two converging planar wall portions 3d and 3e, which connect the curved line 3c' to the second focus" F2 ", to leave there a small opening 3g, (3b) , say about 1.2 - 0.3 mm, such as 0.6 mm.

The wall portions 3d and 3e are assigned a sawtooth shape, so as to be able to absorb or re-reflect away undesirable disturbances, which fall outside the desired aperture angle "a" for the light beam 3a ', generated directly by the light source 3 and / or via reactions of incident light back to the elliptically curved line 3c 'or surface 3c'.

The arrangement with the elliptically curved flat surface 3c and the converging wall portions 3d and 3e are mutually dimensioned so that emitted diverging light beam 3a 'from the aperture 3g, with an optical filter 3g' applied there, has a divergence angle "a" of between 30 ° and 45 °, such as about 40 °.

The light beam 3a ', leaving the aperture 3g, is diverging with edge-assigned light beams assigned the reference numerals 13a', 23a '.

The curved surface 2b and the mirror surface 2b ”are adapted as a parabola line, originating in a vertex point“ V2 ”and having an axis 2b” oriented through or at least close to the opening 3g and focus or focal point “FZ”. 524 663 22 The curved surface 2b and the mirror surface 2b 'constitute a selected part or wall portion (2b') of one half of a parabola line, with its focal point or focus assigned the reference numeral "F3".

Focus “F2” and focus “FS” could advantageously coincide in one embodiment, but have been illustrated in the exemplary embodiment slightly offset from each other along the axis 2b ”, which will be described in more detail below.

The wavefront 3a ”from the mirror surface 2b 'is reflected in the lattice surface 2g” and diffracted to return as a diffracted wavefront (3a ”) towards the mirror surface 2b', in order that as e.g. two diffracted light beams 3f and 3h, with their absorption wavelengths, are reflected towards their respective light receivers 4 and 5.

The reflection angle "b" for the first edge-related light beam 13a 'of the light beam 3a' should be selected between 20 ° and 40 °, preferably between 25 "and 35 °, such as about 30 °.

The angle of reflection 'c' of the second edge-related light beam 23a 'of the beam 3a' should be selected between 40 ° and 80 °, preferably between 50 ° and 70 °, such as about 60 °.

More specifically, the focal point or focus "F2" and the aperture 3g are located closer to the focus "F3", however in a direction towards the vertex "V2", while the aperture 4a of the receiver 4 for the light beam within the receiving lobe 3f is located on the other side of focus "F3" .

The receiver 5, with its aperture 5a, is adapted to receive selected light beams within the receiving beam 3h, at a selected frequency, to serve as a reference signal in the circuit 6.

With the above description of the embodiment according to Figure 2, it becomes apparent that a number of other light receivers, similar to the receiver 4 and / or the receiver 5, can be physically separated and distributed so as to detect different absorption wavelengths or frequencies, corresponding to against and significant for other selected gases. Even if the light receivers 4 and 5 are placed here under the first space "K1", there is nothing to prevent them from being placed above the space "K1".

With a reference to Figures 3 and 4, it is shown that the choice of system design and "B | aze" angles for the flat, latticed and cavity-related, wall surface 2g "is made b | .a. given that the lattice structure in crystalline silicon forms two different crystal planes, with a mutual angle of 70.6 °, which can be used to create a diffraction lattice, with a natural "Blaze" angle "d" of 54.7 °.

This offers an opportunity to create an original in a cheap and easily producible way, which is needed for a tool production and to form a polymer-based replica.

Thus, with reference to fi gur 3, there is shown with the reference numeral a resist / oxide opening and with the reference numeral "Y" a resist / oxide- bfl / Qga- The value assigned to the reference numeral "U" is equal to Y / 2 during the etching and "D" constitutes a value for the lattice constant.

With a reference to där figure 4, a “Littrow” arrangement is illustrated in more detail and which then constitutes an enlargement of a delimited sub-section for the flat surface 2g 'with the lattice structure 2g ".

In the "Littrow" arrangement, an incoming light wave 3a "is allowed to fall at an angle that is close to the" Blaze "angle of the grating.

The light rays within the light wave 3a ”which have a predetermined, determined wavelength of the selected gas and which are important for the invention are reflected diffracted in an almost directly opposite direction and with a very small reflection angle and thus create conditions for attainment. of maximum efficiency, as illustrated in Figure 6.

For a first order diffraction grating, the wavelength becomes equal to "2D sin 55 °" and this gives close to 100% efficiency in this embodiment, since there is no higher order.

For such high angles of approach, no negative arrangements appear either.

This creates the conditions for all light, with a predetermined absorption wavelength, to be able to be reflected back (3a ") in a desired direction and on to a light receiver 4 and 5, respectively.

With regard to focus "F2" for the elliptical shape and the absorption wavelength-related reception, within the receivers 4 and 5, these can not be allowed to coincide, but here a small distance between them is required, which can be regulated according to the embodiment, for example by having focus placed " F2 "on one side focus" F32 and receivers 4 and 5 on the other side focus "FS".

Should focus "F2" coincide with focus "F3", it is required that the flat grating surface 29 "or the grating constant" D "is angled slightly so that the diffracted light beam (3a") is reflected in the mirror surface 2b 'obliquely and with resp. absorption wavelength directed at the receiver 4 or 5.

Should the receiver 4 or 5 be placed in focus "F3", it is also required that focus "F2" is placed next to focus "F3".

Thus, according to the invention, it is indicated that a light source 3 or a virtual light source (3 ') may advantageously be located in or close to a focal point or focus "F3", assigned to the concavely curved surface 2b'.

Alternatively, one or more light receivers 4, 5 may be located close to or in a focal point "F3", assigned to the concavely curved surface 2b '. The optical filter 3g' is adapted to allow the passage of light-related wavelengths within a for the detector system for free spectral range, and said filter is adapted to filter out wavelengths shorter than wavelengths coordinated within the free spectral range.

By "free spectral range" is meant a spectral range which in a calculation point is only illuminated by a spectral order and is thus free from shorter and overlapping wavelengths of another order.

More specifically, the optical filter should shade wavelengths shorter than a selected minimum wavelength.

If higher orders of fundamental frequencies will also be received in the receivers 4, 5, these will be perceived as noise. Measures must therefore be taken with advantage to prevent the occurrence of any higher order frequencies.

The invention will now be further explained in an application according to Figure 5 where a specially shaped and adapted gas cell 2 and a gas sensor are to detect the CO 2 gas content in air with a normal gas mixture. Other gases require different adaptations and a different design for the gas cell 2 and its cavity 2 '.

The gas "G" passes the inlet 21, through the cavity 2 'of the cavity 2' and the outlet 22.

As a light source 3, a white light source is chosen, where i.a. the wavelength ranges fi nns with which are characteristic C02 absorption wavelengths. Although a light bulb or other thermal light source 3 is proposed here, the use of LEDs falls within the scope of the invention. The characteristic absorption wavelength of CO 2 is 4.25 μm, which wavelength is to be diffracted out and received in the receiver 4, another shorter wavelength, say 3.9 μm, is to be received in the receiver 5 and serves there as a reference signal.

A second order wavelength then becomes 2.12 μm and mentioned 3lter 3g 'is intended to bortlter away these and shorter wavelengths.

The circuit 6 evaluates the light intensity in the light receivers 4 and 5 and via comparative circuits 6a the presence of the CO 2 gas is determined as well as the current concentration which is shown on the display surface 7 '.

With reference to Figure 5, the light spectrum and the optical measuring distance that become valid in an evaluation of CO2 gas in a gas mixture within the cavity or space "K2" are shown there. Figure 5 has also introduced current values for current wavelengths.

The filament 30 is enclosed by quartz glass 31 and thus they are de an upper limit, say 5.0 μm.

Via the optical filter 3g 'they lower the lower limit, say 3.0 μm.

The wavefront 3a 'is directed towards the flat surface 2g' with the "Littrow" arrangement 2g "and from there the wavelengths 4.0 - 4.5 μm and 3.9 μm are diffracted and after a reaction in the mirror surface 2b 'these are received by the receiver 4 or the receiver 5.

Figure 6 shows a graph of the change in efficiency with respect to the wavelength for a “Littrow” arrangement and where it appears that for the current wavelengths the efficiency is high. 524 663 27 Figure 7 shows in a graph the detectors 4 resp. 5 wavelength-related reception in relation to the percentage of light source emission and from which graph the high reception for the wavelengths around 4.0 μm and 4.5 μm is evident.

Figure 5 further shows that the active sub-portion (2b ') of the curved surface 2b or the parabolic shape, between the light beams 13a * and 23a', must be located at a distance from a parabola line belonging to the vertex "V2" and close to the said parabolic line focus. or focal point "F3".

Furthermore, the sub-portion (2b ') is limited to a point or section oriented perpendicular or near perpendicular to a parabola line or function assigned axis 2b "and by a related focus or focal point" F3 ".

The invention is of course not limited to the embodiment given above as an example, but may undergo modifications within the scope of the inventive concept illustrated in the appended claims.

Claims (27)

524 663 28 PATENT REQUIREMENTS A gas cell, incorporated in a gas sensor, adapted for the determination of the presence of one or more gases and / or for the determination of the gas concentration exhibiting such gas, comprising a cavity having, with brighter fl-acting properties, defined by wall portions () 2 '), intended to enclose a volume of said gas, a light source (3), adapted to emit a light beam (3a'), directed to be reflected between cavity-associated and opposite wall portions, the light beam being formed by light beams, which, reflected in a concave wall portion (2b), are adapted to be directed at one or fl your light receivers (4,5), which or which is adapted to detect occurring light intensity in one or fl your absorbing wavelength or wavelengths corresponding to the gas, characterized therefrom, that said concavely curved wall portion (2b) is adapted to reflect (2b ') an obliquely received diverging light beam (3a') from the light source ((3 ')) towards a flat grid-assigned cavity member t wall portion (2g '), the reflecting surface (2g ") of which has one or is structured as a" Littrow "arrangement, that the light beam (3a") is adapted to fall towards said flat wall portion at an angle close to the "Blaze" angle of the grating and that one or more absorption wavelengths corresponding to the selected gas within the light beam (3a ") are caused to be reflected and diffracted by said flat wall portion (2g") in a directly opposite direction, to be refracted wavelength in said curved surface (2b ') and directed towards said light receiver (4,5). Gas cell according to claim 1, characterized in that said curved wall portion (2b ') connects to a part ((2b')) of a curved shape representing a parabola. Gas cell according to claim 2, characterized in that said light source (3) appears virtually ((3 ')) in or adjacent to a focal point belonging to a parabola form (Fa). Gas cell according to claim 2 or 3, characterized in that said curved wall portion (2b) has the shape of a parabolic arc, oriented on one side of an axis of a parabolic shape (2b "). Gas cell according to claim 1, characterized in that the flat grid-assigned cavity-associated wall portion (2g ') is assigned to a grid structure (2g') with a "Blaze" angle for reflection in an opposite direction. Gas cell according to claim 5, characterized in that the grating structure is adapted to create only a first, and / or a second, order diffraction grating. Gas cell according to Claim 1, characterized in that the "Baze" angle is chosen between 50 ° and 60 °. Gas cell according to claim 1, characterized in that one or fl your light receivers are located close to a virtual light source and with their receiving lobes directed towards the curved surface (2b '). Gas cell according to claim 1, characterized in that said cavity is formed by at least one polymer-based replica, which has been treated to impart light-reflected properties to the wall portions. Gas cell according to claim 1, characterized in that the light source is constituted by an incoherent light source, for generating a wavelength spectra within the 1R range. Gas cell according to Claim 1 or 8, characterized in that a light source or virtual light source is located in or close to a focal point (F3), assigned to the concavely curved surface (2b). Gas cell according to Claim 1, 8 or 11, characterized in that one or more of its light receivers (4, 5) are located close to or in a focal point (F3), assigned to the concavely curved surface (2b). 524 663 30 Gas cell according to one of the preceding claims, characterized in that a physical light source is located in one focal point of an elliptical shape and in that a virtual light source ((3 ')) located in an aperture appears in the other focal point (F2). (3g) with an optical filter (3g '). Gas cell according to Claim 13, characterized in that the optical filter is adapted to allow the passage of light-related wavelengths within a free spectral range applicable to the detector system. Gas cell according to claim 13 or 14, characterized in that said optical filter is adapted to filter out wavelengths shorter than wavelengths coordinated within the free spectral range. Gas cell according to claim 1, characterized in that said cavity (2 ') is formed as two spaces ("K1", "K2"), where a space ("K1") comprises a physical light source and a reactor. Gas cell according to Claim 16, characterized in that the second space ("K2") serves the function of a measuring chamber offering light reflections. Gas cell according to Claim 16, characterized in that the first space ("K1") has a partially elliptical sub-section ("K1"). Gas cell according to Claim 18, characterized in that the terminating part ((K1 ")) has a tapered shape. Gas cell according to claim 19, characterized in that the second sub-portion ((K1 ")) is delimited by two converging wall portions (3d, 3e). Gas cell according to claim 20, characterized in that said wall portions (3d, 3e) are prepared for or shaped to exhibit deficient reflective properties. 524 663 31 Gas cell according to claim 20, characterized in that said converging wall portions (3d, 3e) form an angle corresponding to a diverging angle or aperture angle (a) of a emitted light beam (3a ') from the light source (3,3'), Gas cell according to Claim 1, characterized in that a number of light receivers (4,5) are coordinated on one side of a cavity-associated space (“K1”). Gas cell according to claim 23, characterized in that a number of light receivers are coordinated on the opposite side of said space. Gas cell according to claim 1, characterized in that the flat grid-assigned cavity-associated wall portion (29) is assigned a direction where a virtual extension connects to or passes close to the vertex ("V2") of the concavely smoked wall portion (2b). ). Gas cell according to Claim 1, 16 or 17, characterized in that a measuring distance belonging to a measuring chamber is extended by utilizing an optical measuring distance within the first space ("K1"). Gas cell according to claim 26, characterized in that said first space ("K1") is provided with an inlet (21 ') and an outlet (22') for the gas (G) intended for the measurement.